An ion detection system for a detecting a quantity of ions exiting from a mass analyzer of a mass spectrometer comprises: (a) photon generating means configured to receive the quantity of ions and to generate a quantity of photons that is proportional to the quantity of ions; (b) a linear array of photo-detectors configured along a line for detecting a variation of a portion of the quantity of generated photons along the line; and (c) an optical system for directing the portion of the quantity of photons from the photon generating means to the linear array of photo-detectors comprising: (c1) a first cylindrical lens having a first lens axis disposed parallel to the line; (c2) a second cylindrical lens or rod lens having a second lens axis disposed parallel to the line; and a doublet lens.
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1. An ion detection system for a detecting a quantity of ions exiting from a mass analyzer of a mass spectrometer, the ion detection system comprising:
(a) photon generating means configured to receive the quantity of ions and to generate a quantity of photons that is proportional to the quantity of ions;
(b) a linear array of photo-detectors configured along a line for detecting a variation of a portion of the quantity of generated photons along the line; and
(c) an optical system for directing the portion of the quantity of photons from the photon generating means to the linear array of photo-detectors comprising:
(c1) a first cylindrical lens disposed between the photon generating means and the linear array of photo-detectors and having a first lens axis that is disposed parallel to the line;
(c2) a second cylindrical lens or a rod lens disposed between the first cylindrical lens and the linear array of photo-detectors and having a second lens axis that is disposed parallel to the line; and
(c3) a doublet lens disposed between the photon generating means and the first cylindrical lens.
5. An ion detection system for a detecting a quantity of ions exiting from a mass analyzer of a mass spectrometer, the ion detection system comprising:
(a) photon generating means configured to receive the quantity of ions and to generate a quantity of photons that is proportional to the quantity of ions;
(b) a linear array of photo-detectors configured along a line for detecting a variation of a portion of the quantity of generated photons along the line; and
(c) an optical system for collecting the portion of the quantity of photons from an area of the photon generating means and transferring the portion of the quantity of photons from the area of the photon generating means to the linear array of photo-detectors, said optical system comprising:
(c1) a first cylindrical lens disposed between the photon generating means and the linear array of photo-detectors and having a first lens axis that is disposed perpendicular to the line;
(c2) a second cylindrical lens disposed between the first cylindrical lens and the linear array of photo-detectors and having a second lens axis that is disposed parallel to the line; and
(c3) a plano-convex lens disposed between the photon generating means and the first cylindrical lens.
14. An ion detection system for a detecting a quantity of ions exiting from a mass analyzer of a mass spectrometer, the ion detection system comprising:
an assembly of one or more microchannel plates disposed at an ion exit end of the mass analyzer, the assembly having a front end disposed so as to receive the quantity of ions and a back end;
a first and a second electrode disposed at the front and back ends, respectively, of the assembly of microchannel plates;
at least one voltage source electrically coupled to the first, second and third electrodes;
a substrate plate comprising a front face disposed facing the microchannel plate assembly and a back face and having a phosphorescent material disposed on the front face;
a third electrode disposed in contact with the front face of the substrate plate;
a linear array of photo-detectors configured along a line; and
an optical system optically coupled between the back face of the substrate plate and the linear array of photo-detectors, said optical system comprising:
a first cylindrical lens having a first lens axis that is disposed perpendicular to the line;
a second cylindrical lens disposed between the first cylindrical lens and the linear array of photo-detectors and having a second lens axis that is disposed parallel to the line; and
a plano-convex lens disposed between the back face of the substrate plate and the first cylindrical lens.
10. An ion detection system for a detecting a quantity of ions exiting from a mass analyzer of a mass spectrometer, the ion detection system comprising:
an assembly of one or more microchannel plates disposed at an ion exit end of the mass analyzer, the assembly having a front end disposed so as to receive the quantity of ions and a back end;
a first and a second electrode disposed at the front and back ends, respectively, of the assembly of microchannel plates;
at least one voltage source electrically coupled to the first, second and third electrodes;
a substrate plate comprising a front face disposed facing the microchannel plate assembly and a back face and having a phosphorescent material disposed on the front face;
a third electrode disposed in contact with the front face of the substrate plate;
a linear array of photo-detectors configured along a line; and
an optical system optically coupled between the back face of the substrate plate and the linear array of photo-detectors, said optical system comprising:
a first cylindrical lens disposed having a first lens axis that is disposed parallel to the line;
a second cylindrical lens or a rod lens disposed between the first cylindrical lens and the linear array of photo-detectors and having a second lens axis that is disposed parallel to the line; and
a doublet lens disposed between the back face of the substrate plate and the first cylindrical lens.
2. An ion detection system as recited in
(a1) electron generating means configured to receive the quantity of ions and to generate a quantity of electrons that is proportional to the quantity of ions; and
(a2) a phosphor screen disposed on a surface of a substrate and configured to receive the quantity of generated electrons and to generate the quantity of photons in proportion to the quantity of generated electrons.
3. An ion detection system as recited in
an assembly of one or more microchannel plates (MCPs), the assembly comprising a first end facing the mass analyzer and a second end facing the phosphor screen; and
an electrode disposed at the first end and an electrode disposed at the second end of the assembly.
4. An ion detection system as recited in
an assembly of one or more metal channel dynodes, the assembly comprising a first end facing the mass analyzer and a second end facing the phosphor screen.
6. An ion detection system as recited in
(a1) electron generating means configured to receive the quantity of ions and to generate a quantity of electrons that is proportional to the quantity of ions; and
(a2) a phosphor screen disposed on a surface of a substrate and configured to receive the quantity of generated electrons and to generate the quantity of photons in proportion to the quantity of generated electrons.
7. An ion detection system as recited in
an assembly of one or more microchannel plates (MCPs), the assembly comprising a first end facing the mass analyzer and a second end facing the phosphor screen; and
an electrode disposed at the first end and an electrode disposed at the second end of the assembly.
8. An ion detection system as recited in
an assembly of one or more metal channel dynodes, the assembly comprising a first end facing the mass analyzer and a second end facing the phosphor screen.
9. An ion detection system as recited in
11. An ion detection system as recited in
12. An ion detection system as recited in
13. An ion detection system as recited in
a fourth electrode disposed in contact with the front face of the substrate plate; and
an electrometer electrically coupled to the fourth electrode.
15. An ion detection system as recited in
16. An ion detection system as recited in
17. An ion detection system as recited in
a fourth electrode disposed in contact with the front face of the substrate plate; and
an electrometer electrically coupled to the fourth electrode.
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This application is a Continuation of and claims the right of priority to U.S. application Ser. No. 14/561,166, filed on Dec. 4, 2014 and titled “Recording Spatial and Temporal Properties of Ions Emitted from a Quadropole Mass Filter”, now U.S. Pat. No. 9,355,828, the disclosure of which is incorporated by reference herein in its entirety.
The present invention relates to the field of mass spectrometry. More particularly, the present invention relates to a mass spectrometer system and method in which ions exiting a mass analyzer are converted to a quantity of photons that are focused to a line and a variation of the quantity and position of photons is measured parallel to the focused line.
Typically, a multipole mass filter (e.g., a quadrupole mass filter) may be used for mass analysis of ions provided within a continuous ion beam. A quadrupole field is produced within the quadrupole apparatus by dynamically applying electrical potentials on configured parallel rods arranged with four-fold symmetry about a long axis, which comprises an axis of symmetry that is conventionally referred to as the z-axis. By convention, the four rods are described as a pair of “x-rods” and a pair of “y-rods”. At any instant of time, the two x-rods have the same potential as each other, as do the two y-rods. The potential on the y-rods is inverted with respect to the x-rods. The “x-direction” or “x-dimension” is taken along a line connecting the centers of the x-rods. The “y-direction” or “y-dimension” is taken along a line connecting the centers of the y-rods.
Relative to the constant potential along the z-axis, the potential on each set of rods can be expressed as a constant DC offset plus an RF component that oscillates rapidly (with a typical frequency of about 1 MHz). The DC offset on the x-rods is positive so that a positive ion feels a restoring force that tends to keep it near the z-axis; the potential in the x-direction is like a well. Conversely, the DC offset on the y-rods is negative so that a positive ion feels a repulsive force that drives it further away from the z-axis; consequently, the potential in the x,y-plane is in the form of a saddle.
An oscillatory RF component is applied to both pairs of rods. The RF phase on the x-rods is the same and differs by 180 degrees from the phase on the y-rods. Ions move inertially along the z-axis from the entrance of the quadrupole to a detector often placed at the exit of the quadrupole. Inside the quadrupole, ions have trajectories that are separable in the x and y directions. In the x-direction, the applied RF field carries ions with the smallest mass-to-charge ratios out of the potential well and into the rods. Ions with sufficiently high mass-to-charge ratios remain trapped in the well and have stable trajectories in the x-direction; the applied field in the x-direction acts as a high-pass mass filter. Conversely, in the y-direction, only the lightest ions are stabilized by the applied RF field, which overcomes the tendency of the applied DC to pull them into the rods. Thus, the applied field in the y-direction acts as a low-pass mass filter. Ions that have both stable component trajectories in both x- and y-directions pass through the quadrupole to reach the detector.
In operation, the DC offset and RF amplitude applied to a quadrupole mass filter is chosen so as to transmit only ions within a restricted range of mass-to-charge (m/z) ratios through the entire length of the quadrupole. Such apparatuses can be operated either in the radio frequency (RF)-only mode or in an RF/DC mode. Depending upon the particular applied RF and DC potentials, only ions of selected m/z ratios are allowed to pass completely through the rod structures, whereas the remaining ions follow unstable trajectories leading to escape from the applied multipole field. When only an RF voltage is applied between predetermined electrodes, the apparatus serves to transmit ions in a wide-open fashion above some threshold mass. When a combination of RF and DC voltages is applied between predetermined rod pairs there is both an upper cutoff mass as well as a lower cutoff mass, such that only a restricted range of m/z ratios (i.e., a pass band) passes completely through the apparatus. As the ratio of DC to RF voltage increases, the transmission band of ion masses narrows so as to provide for mass filter operation, as known and as understood by those skilled in the art. As is further known, the amplitudes of the DC and RF voltages may be simultaneously varied, but with the DC/RF ratio held nearly constant but varied to maintain a uniform pass band, such that the pass band is caused to systematically “scan” a range of m/z ratios. Detection of the quantity of ions passed through the quadrupole mass filter over the course of such scanning enables generation of a mass spectrum.
Typically, such quadrupole mass filters are employed as a component of a triple stage mass spectrometer system. By way of non-limiting example,
The example mass spectrometer system 1 of
During conventional operation of a multipole mass filter, such as the quadrupole mass filter Q3 shown in
U.S. Pat. No. 8,389,929, which is assigned to the assignee of the present invention and which is incorporated by reference herein in its entirety, teaches a quadrupole mass filter method and system that discriminates among ion species, even when both are simultaneously stable, by recording where the ions strike a position-sensitive detector as a function of the applied RF and DC fields. When the arrival times and positions are binned, the data can be thought of as a series of ion images. Each observed ion image is essentially the superposition of component images, one for each distinct m/z value exiting the quadrupole at a given time instant. The same patent also teaches methods for the prediction of an arbitrary ion image as a function of m/z and the applied field. Thus, each individual component image can be extracted from a sequence of observed ion images by mathematical deconvolution or decomposition processes, as further discussed in the patent. The mass-to-charge ratio and abundance of each species necessarily follow directly from the deconvolution or decomposition.
The inventors of U.S. Pat. No. 8,389,929 recognized that ions of different m/z ratios exiting a quadrupole mass filter may be discriminated, even when both ions are simultaneously stable (that is, have stable trajectories) within the mass filter by recording where the ions strike a position-sensitive detector as a function of the applied RF and DC fields. The inventors of U.S. Pat. No. 8,389,929 recognized that such operation is advantageous because when a quadrupole is operated in, for example, a mass filter mode, the scanning of the device that is provided by ramped RF and DC voltages naturally varies the spatial characteristics with time as observed at the exit aperture of the instrument. Specifically, ions manipulated by a quadrupole are induced to perform a complex 2-dimensional oscillatory motion on the detector cross section as the scan passes through the stability region of the ions. All ion species of respective m/z ratios express exactly the same motion, at the same Mathieu parameter “a” and “q” values, but at different respective RF and DC voltages and at different respective times. The ion motion (i.e., for a cloud of ions of the same m/z but with various initial displacements and velocities) may be characterized by the variation of a and q, this variation influencing the position and shape cloud of ions exiting the quadrupole as a function of time. For two masses that are almost identical, the sequence of their respective oscillatory motions is essentially the same and can be approximately related by a time shift.
The aforementioned U.S. Pat. No. 8,389,929 teaches, inter alia, a mass spectrometer instrument having both high mass resolving power and high sensitivity, the mass spectrometer instrument including: a multipole configured to pass an abundance of one or more ion species within stability boundaries defined by applied RF and DC fields; a detector configured to record the spatial and temporal properties of the abundance of ions at a cross-sectional area of the multipole; and a processing means. The data acquired by the so-configured detector can be thought of as a series of ion images. Each observed ion image is essentially the superposition of component images, one for each distinct m/z value exiting the quadrupole at a given time instant. The aforementioned patent also provides for the prediction of an arbitrary ion image as a function of in/z and the applied field. As a result, each individual component can be extracted from a sequence of observed ion images by mathematical deconvolution or decomposition processes which generate the mass-to-charge ratio and abundance of each species. Accordingly, high mass resolving power may be achieved under a wide variety of operating conditions, a property not usually associated with quadrupole mass spectrometers.
The teachings of the aforementioned U.S. Pat. No. 8,389,929 exploit the varying spatial characteristics by collecting the spatially dispersed ions of different m/z even as they exit the quadrupole at essentially the same time.
As the ion approaches the exit of the stability region, a similar effect happens, but in reverse and involving the x-component rather than the y-component. The cloud gradually elongates in the horizontal direction and the oscillations in this direction increase in magnitude until the cloud is carried across the left and right boundaries of the image. Eventually, both the oscillations and the length of the cloud increase until the transmission decreases to zero.
To illustrate operability by way of an example, the first surface of the MCP assembly 13 can be floated to 10 kV, (i.e., +10 kV when configured for negative ions and −10 kV when configured to receive positive ions), with the second surface floated to +12 kV and −8 kV respectively, as shown in
The example biasing arrangement of
The biasing arrangement of the detector system 20 (
The photons p emitted by the phosphor coated fiber optic plate or aluminized phosphor screen 15 are captured and then converted to electrons which are then translated into a digital signal by a two-dimensional camera component 25 (
Each of the anodes of the two-dimensional camera 25 shown in
The time and position mass spectrometer ion detector systems taught in the aforementioned U.S. Pat. No. 8,389,929, as exemplified by the accompanying
In order to implement the above-described desirable improvements, the inventors of the present application have recognized that the full two-dimensional imaging capability described in U.S. Pat. No. 8,389,929 is unnecessary for adequate data processing. Thus, in one instance, the previously described two-dimensional array of light-sensitive pixels may be simply replaced by two one-dimensional pixel arrays—each such one-dimensional array possibly comprising a linear photo-detector array, such as a line camera, and oriented so as to detect a distribution pattern of ions exiting a quadrupole device in a respective one of the x- and y-dimensions. Since the ion motion of interest is orthogonal in the x- and y-dimensions, most information can be retained by simply binning the original two-dimensional image into an x-array and a y-array as previously taught. Here, the binning is accomplished by optically compressing an original two dimensional distribution of phosphor-derived photons along the y-direction so as to be detected by individual photon detecting pixels of the x-array of and also optically compressing the distribution of photons along the x-direction so as to be detected by individual photon detecting pixels of the y-array. Optical compression is accomplished with the use of a novel 2-dimensional to 1-dimensional optical component developed by the inventors. Such an arrangement significantly reduces the number of pixels that must be electronically read.
The inventors of the present application have further recognized that, in many circumstances, a sufficient quantity of time and position data may be obtained by only employing a single one-dimensional photo detector array—either an x-array or a y-array—as described in the above paragraph. The elimination of one of the detector arrays enables the optional incorporation of an additional detector comprising either an electrometer to detect electrons generated from ions exiting a quadrupole or an additional photodetector, such as a photo-multiplier tube or silicon photomultiplier, so as to detect photons generated from those electrons by phosphorescence. The additional detector provides additional conventional features, such as pulse counting.
According to a first aspect of the present teachings, an ion detection system for detecting a quantity of ions exiting from a mass analyzer of a mass spectrometer is provided, the ion detection system comprising: (a) photon generating means configured to receive the quantity of ions and to generate a quantity of photons that is proportional to the quantity of ions; (b) a light collection lens optically coupled to the photon generating means and configured to transmit a beam of the generated photons; (c) line focusing means operable to focus at least a first portion of the beam to a line; and (d) a linear array of photo-detectors configured to detect a variation of the quantity of generated photons along the focused line. The ions exiting from the mass analyzer may exit from a quadrupole apparatus.
The photon generation means may comprise: (a1) electron generating means configured to receive the quantity of ions and to generate a quantity of electrons that is proportional to the quantity of ions; and (a2) a phosphor screen disposed on a surface of a substrate and configured to receive the quantity of generated electrons and to generate the quantity of photons in proportion to the quantity of generated electrons. The electron generating means may comprise an assembly of microchannel plates (MCPs) or metal channel dynodes, the assembly comprising a first end facing the mass analyzer and a second end facing the phosphor screen; and an electrode disposed at the first end and an electrode disposed at the second end of the assembly.
In some embodiments the line focusing means comprises a cylindrical lens. In some embodiments, the line-focusing means comprises a beam compressor apparatus (I) a prismatic core section comprising a plurality of waveguide plates disposed in a stacked arrangement parallel to two prism basal faces; an entrance face that receives the generated photons; and an exit face from which the generated photons are emitted, the core section comprising a taper from the entrance to the exit face; and (II) a reflective coating disposed on at least one face of the prismatic core section other than the entrance and exit faces. The beam compressor apparatus may be optically coupled between a cylindrical lens of the line-focusing means and the linear array of photo-detectors. In some embodiments, the linear array of photo-detectors comprises a line camera.
In various embodiments, the ion detection system may include: (e) an additional photodetector optically coupled to the light collection lens so as to receive a second portion of the beam that is not focused by the line focusing means. Some of these embodiments may also include an optical beam splitter configured to receive the beam and to divide the beam into the first and second portions. Some embodiments having the additional photodetector may include a two-dimensional optical parabolic concentrator optically coupled between the light collection lens and the additional photodetector. The additional photodetector may comprise a photomultiplier tube or silicon photomultiplier. Alternatively, in those embodiments in which a beam splitter is present, the additional photodetector may comprise a second linear array of photo-detectors configured to detect a variation of the quantity of generated photons along the second focused line; and a second line focusing means operable to focus the second portion of the beam to a second line on the second linear array of photodetectors. The second line-focusing means may comprise a cylindrical lens, a beam compressor apparatus as described above or both a cylindrical lens and a beam compressor apparatus. In yet other alternative embodiments in which the photon generating means includes a phosphor screen disposed on a surface of a substrate and configured to receive the quantity of generated electrons, the additional photodetector may comprise an electrometer that is electrically coupled to an electrode in contact with substrate that collects the quantity of electrons. An electronic amplifier may be electrically coupled between the electrode and the electrometer.
According to a second aspect of the present teachings, A method of detecting a quantity of ions emitted from a mass analyzer of a mass spectrometer is disclosed, the method comprising: (i) generating a quantity of photons corresponding to the quantity of ions; (ii) focusing a light beam comprising at least a first portion of the quantity of photons to a focused line; and (iii) detecting a variation of the at least a first portion of the quantity of generated photons along the focused line using a linear array of photodetectors, wherein the variation of the quantity of generated photons along the focused line corresponds to a variation of the quantity of ions emitted from the mass analyzer parallel to a first cross-section direction of the mass analyzer.
In some embodiments, the method may further comprise (iv) detecting an intensity of a second portion of the quantity of generated photons using an additional photodetector. The additional photodetector may comprise a second linear array of photodetectors, in which case the second portion of the quantity of photons may be focused onto the second linear array of photodetectors as a second focused line, wherein a variation of the second portion of the quantity of generated photons along the second focused line corresponds to a variation of the quantity of ions emitted from the mass analyzer parallel to a second cross-section direction of the mass analyzer, the second cross-section direction being orthogonal to the first cross-section direction. In some embodiments, the first and second portions of the quantity of generated photons may be separated using a beam splitter. In various embodiments, the step (i) of generating the quantity of photons may comprise: generating a quantity of electrons corresponding to the quantity of ions; and generating the quantity of photons, wherein the generated quantity of photons corresponds to the generated quantity of electrons. In such embodiments, the quantity of generated electrons may be measured using an electrometer.
According to a third aspect of the present teachings, an ion detection system for a detecting a quantity of ions exiting from a mass analyzer of a mass spectrometer is provided, the ion detection system comprising: (a) an assembly of one or more microchannel plates disposed at an ion exit end of the mass analyzer, the assembly having a front end disposed so as to receive the quantity of ions and a back end; (b) a first and a second electrode disposed at the front and back ends, respectively, of the assembly of microchannel plates; (c) at least one voltage source electrically coupled to the first, second and third electrodes; (d) a substrate plate comprising a front face disposed facing the microchannel plate assembly and a back face and having a phosphorescent material disposed on the front face; (e) a third electrode disposed in contact with the front face of the substrate plate; (f) a light collection lens optically coupled to the back face of the substrate plate; (g) a line focusing means optically coupled to the light collection lens; and (h) a linear array of photo-detectors disposed at a focus of the line focusing means.
The system may further comprise an additional photodetector system optically coupled to the light collection lens. In some embodiments, the additional photodetector system comprises an additional linear array of photodetectors, and the system further comprises: an optical beam splitter optically coupled between the light collection lens and the line focusing means; and a two-dimensional optical parabolic concentrator optically coupled between the light collection lens and the additional linear array of photodetectors, wherein the additional linear array of photodetectors is disposed at a focus of the second line focusing means. In some embodiments, the additional photodetector system comprises a photomultiplier tube or silicon photomultiplier. In such embodiments, the system may further comprise: an optical beam splitter optically coupled between the light collection lens and the line focusing means; and a two-dimensional optical parabolic concentrator optically coupled between the optical beam splitter and the additional photodetector system. Some embodiments of the system may include: a fourth electrode disposed in contact with the front face of the substrate plate; and an electrometer electrically coupled to the fourth electrode.
Fresnel lenses may be employed in place of conventional smooth surface lenses in any of the disclosed embodiments. In such cases, most of the optics assembly is an arrangement of planer devices comprising Fresnel lenses and possibly mirrors or beam splitters. In the case of embodiments that employ a linear array of photodetectors, the linear array may be significantly longer than the original phosphor image, such as when the linear array comprises an array of discrete silicon photomultipliers. In such cases, it is generally desirable to compress the image in one dimension and enlarge it in the other. Such an image transfer scheme may be accomplished with a combination of mutually-orthogonally-disposed cylindrical lenses, disposed between the phosphor and the detector array. The long throw this optical arrangement requires may be folded using mirrors or prisms to reduce the overall optics footprint. In the embodiments that comprise a beam splitter to image the two dimensional image, these mirrors may be arranged to throw the two linear images onto the same plane thereby facilitating fabrication of the sensor arrays on a single printed circuit board (PCB) or on two small daughter PCBs attached to a carrier PCB. In the latter case, daughter boards are not necessarily co-planar but rather simply mounted to a single carrier board and the images may be perpendicular to that board.
The above noted and various other aspects of the present invention will become further apparent from the following description which is given by way of example only and with reference to the accompanying drawings, not drawn to scale, in which:
The following description is presented to enable any person skilled in the art to make and use the invention, and is provided in the context of a particular application and its requirements. Various modifications to the described embodiments will be readily apparent to those skilled in the art and the generic principles herein may be applied to other embodiments. Thus, the present invention is not intended to be limited to the embodiments and examples shown but is to be accorded the widest possible scope in accordance with the features and principles shown and described. The particular features and advantages of the invention will become more apparent with reference to the appended
Components shown on the right hand side of the substrate plate 109 in
Each of the two light beam portions is refracted by a respective lens or lens system 120a, 120b so as to project a two-dimensional image of the phosphor screen onto a face of a respective image compressor device 71a, 71b (discussed in greater detail below). Two such image planes are depicted as image planes 129 in
According to the configuration illustrated in
As illustrated in
Assuming each linear photo-detector array comprises 64 pixels, the configuration illustrated in
Each waveguide 74 of the compressor device 71 may be optically coupled to a single pixel 133 of a photo-detector array 132 (see
In the system 200, the beam splitter 116 divides a light beam generated at the phosphor-coated screen 107 into first and second light beam portions, as previously described with reference to the system 100 depicted in
The beam splitter may, in some embodiments, divide the light into roughly first and second light beam portions of approximately equal intensity. However, the intensities of the first and second light beam portions may, in other embodiments, be configured to be unequal. For example, if the two detection systems are found to have unequal gain or sensitivity, then the beam splitter may be configured to direct a greater proportion of the light beam to the less-sensitive detector. Also, although the photo-multiplier tube is shown as receiving a reflected light beam portion from the beam splitter 116 in
Although a photomultiplier tube 236 is shown as a non-imaging detector in
Some ion cloud imaging information may be lost in the system 200, relative to the system 100 (
In the case of embodiments that employ a linear array of photodetectors, an image of a phosphor-bearing surface must be compressed into a line, the compression being along a dimension that is orthogonal to the length of the array. However, depending on the relative sizes of the phosphor screen and the detector, it may be necessary to either compress or magnify the image along a direction parallel to the linear array. (Note that the dimensions of a phosphor screen, as used herein, will generally be approximately equivalent to the dimensions of a mass analyzer from which ions are emitted.) Conventional line cameras based on charge-coupled-device (CCD) technology generally comprise approximately two-thousand pixels where each such pixel is approximately 10-20 μm in size. When such line cameras are employed, for instance, to detect phosphorescence generated from ions emitted from a quadrupole device having dimensions of 12 mm×12 mm, essentially no magnification or compression is required parallel to the length of the photo-detector array.
In light of the above considerations, simple optical configurations employing a cylindrical lens such as shown in
The optics configuration shown in
Recently, a new type of line camera comprising an array of discrete silicon photomultipliers has become available. Such line cameras may be constructed, for example, from silicon photomultipliers provided commercially by SensL™ of Cork, Ireland. The pixels in such a line camera are significantly larger than those in line cameras employing CCD technology. For example, a sixty-four-element row of 1-mm active area SensL devices requires space between individual photo-detector sensors such that the center to center spacing is 1.7 mm. Thus, a sixty-four-element array of such devices requires an optics configuration that generates an image that is magnified to a size of over 100 mm in one dimension while being compressed to 1 mm in the orthogonal dimension.
The optics configuration shown in
One of ordinary skill in the optics arts would readily understand how to construct alternative optical systems for transforming a two-dimensional image (e.g., of a phosphor screen) into a focused or nearly focused line that is transferred onto a linear detector system. For example, U.S. Pat. No. 5,513,201, in the name of inventors Yamaguchi et al. and hereby incorporated by reference herein in its entirety, teaches a large number of image rotation designs that are relevant for transferring each one-dimensional compressed image to a linear sensor.
In the description of the invention herein, it is understood that a word appearing in the singular encompasses its plural counterpart, and a word appearing in the plural encompasses its singular counterpart, unless implicitly or explicitly understood or stated otherwise. Furthermore, it is understood that for any given component or embodiment described herein, any of the possible candidates or alternatives listed for that component may generally be used individually or in combination with one another, unless implicitly or explicitly understood or stated otherwise. Moreover, it is to be appreciated that the figures, as shown herein, are not necessarily drawn to scale, wherein some of the elements may be drawn merely for clarity of the invention. Also, reference numerals may be repeated among the various figures to show corresponding or analogous elements. Additionally, it will be understood that any list of such candidates or alternatives is merely illustrative, not limiting, unless implicitly or explicitly understood or stated otherwise. In addition, unless otherwise indicated, numbers expressing quantities of ingredients, constituents, reaction conditions and so forth used in the specification and claims are to be understood as being modified by the term “about.”
The discussion included in this application is intended to serve as a basic description. The present invention is not to be limited in scope by the specific embodiments described herein, which are intended as single illustrations of individual aspects of the invention, and functionally equivalent methods and components are within the scope of the invention. For example, according to some embodiments, the electron-generating means, shown as microchannel plates (MCPs) in the drawings, may be replaced by a set of one or more metal channel dynodes. Each such metal channel dynode (MCD) may comprise a metal electrode plate having a plurality of perforations or channels therethrough. At the first MCD, ions emitted from the mass analyzer are neutralized by impact with the metal plate or with the interior walls of the perforations or channels and at least a portion of their kinetic energy is released as kinetic energy of ejected secondary electrons. Subsequent MCD plates of a stack of such plates may similarly further amplify the quantity of secondary electrons. If the metal channel dynodes are coated with an appropriate enhancer substance such as magnesium oxide or any other enhancer (generally, a metal oxide), the conversion efficiency should be as good as the input surface of an MCP. Indeed, various modifications of the invention, in addition to those shown and described herein will become apparent to those skilled in the art from the foregoing description and accompanying drawings. Such modifications are intended to fall within the scope of the appended claims. Any patents, patent applications, patent application publications or other literature mentioned herein are hereby incorporated by reference herein in their respective entirety as if fully set forth herein, except that, in the event of any conflict between the incorporated reference and the present specification, the language of the present specification will control.
Schoen, Alan E., Smith, Johnathan Wayne
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